The nature of the link between potassium transport and phosphate transport in Escherichia coli.

A series of mutants of Escherichia coli, combining defects in either of the two phosphate transport systems with defects in one or more of the potassium transport systems, was used to study the nature of the previously observed obligatory requirement for each one of these ions in the transport of the other. The results show that no pair of systems is obligatorily linked, and that either ion can be transported by any one of its systems, provided that a means of entry for the other ion is available. Furthermore, in the total absence of Pi, K+ entry accompanies the transport of other anions, such as aspartate, glutamate, sn-glycero-3-phosphate and glucose 6-phosphate. The results indicate that Pi and the other anions enter by symport with protons, and that a simultaneous K+/H+ exchange, which would serve to maintain the intracellular pH, is responsible for the observed K+ 'symport' with these anions.     

Osmoregulation by potassium transport in Escherichia coli

Abstract Cell turgor pressure determines the extent of K⁺ accumulation by Escherichia coli cells. K⁺ influx is mediated both by a constitutive system with a low affinity for K⁺ (Trk) and by an inducible high affinity system (Kdp). K⁺ efflux is controlled by as yet unidentified but independent systems. Cell K⁺ concentration may be the link between growth in media of high osmolarity and the concomitant accumulation of compatible solutes such as betaine.     

proP-mediated proline transport also plays a role in Escherichia coli osmoregulation.

Shikimate kinase II was purified to near homogeneity from an Escherichia coli strain which overproduced the enzyme. The apparent Km of this isoenzyme for shikimate was 200 microM, and for ATP it was 160 microM. The Km for shikimate is approximately 100-fold lower than the Km of shikimate kinase I, suggesting that shikimate kinase II is the isoenzyme normally functioning in aromatic biosynthesis. Shikimate kinase II is dependent on metal ions for activity.     

The relationship between the electrochemical proton gradient and active transport in Escherichia coli membrane vesicles.

In the previous paper [ramos, S., and Kaback, H.R. (1977), Biochemistry 16 (preceding paper in this issue)], it was demonstrated that Escherichia coli membrane vesicles generate a large electrochemical proton gradient (delta-muH+) under appropriate conditions, and some of the properties of delta-muH+ and its component forces [i.e., the membrane potential (delta psi) and the chemical gradient of protons (deltapH)] were described. In this paper, the relationship between delta-muH+, delta psi, and deltapH and the active transport of specific solutes is examined. Addition of lactose or glucose 6-phosphate to membrane vesicles containing the appropriate transport systems results in partial collapse of deltapH, providing direct evidence for the suggestion that respiratory energy can drive active transport via the pH gradient across the membrane. Titration studies with valinomycin and nigericin lead to the conclusion that, at pH 5.5, there are two general classes of transport systems: those that are driven primarily by delta-muH+ (lactose, proline, serine, glycine, tyrosine, glutamate, leucine, lysine, cysteine, and succinate) and those that are driven primarily by deltapH (glucose 6-phosphate, D-lactate, glucuronate, and gluconate). Importantly, however, it is also demonstrated that at pH 7.5, all of these transport systems are driven by delta psi which comprises the only component of delta-muH+ at this external pH. In addition, the effect of external pH on the steady-state levels of accumulation of different solutes is examined, and it is shown that none of the pH profiles correspond to those observed for delta-muH+, delta psi, or deltapH. Moreover, at external pH values above 6.0-6.5, delta-muH+ is insufficient to account for the concentration gradients established for each substrate unless the stoichiometry between protons and accumulated solutes is greater than unity. The results confirm many facets of the chemiosmotic hypothesis, but they also extend the concept in certain important respects and allow explanations for some earlier observations which seemed to preclude the involvement of chemiosmotic phenomena in active transport.     

Thallous ion is accumulated by potassium transport systems in Escherichia coli.

The accumulation of 204T1+ by Escherichia coli occurs primarily via either of two K+ transport systems called Kdp and TrkA. T1+ influx is inhibited and T1+ efflux is stimulated by the addition of K+ to the assay medium. Mutants defective in both the Kdp and TrkA systems accumulate little T1+. Uptake of triphenylmethylphosphonium, a lipid-soluble cation whose distribution is widely used to estimate the membrane electrical potential in bacteria, occurs to about the same extent in mutants that accumulate little T1+ as in strains that accumulate T1+ to high levels. These findings indicate that T1+ may be useful as a probe of bacterial K+ transport systems but is not a reliable indicator of the membrane electrical potential in E. coli.     

The electrochemical proton gradient and phenylalanine transport in Escherichia coli irradiated with near-ultraviolet light.

Irradiation of Escherichia coli with near-ultraviolet (near-UV) light diminished the electrochemical proton gradient and the accumulation of L-phenylalanine. Inhibitors known to collapse the proton gradient and the comparison of two techniques measuring the electrical potential substantiated the estimates made. At several fluences (doses), a linear relationship was observed between the phenylalanine gradient and the combined electrical and chemical potentials (the electrochemical proton gradient), suggesting a close coupling between them. However, additional effects of near-UV light on the phenylalanine permease were not discounted. The combined potentials provided sufficient energy for the observed accumulation of phenylalanine, assuming a proton to amino acid cotransport ratio of 1. An increase in membrane permeability did not contribute to the loss of phenylalanine transport, as shown by an increase in the rate and extent of alpha-methylglucoside uptake.     

Linked transport of phosphate, potassium ions and protons in Escherichia coli.

Pi entry into Escherichia coli cells through either of the two Pi-transport systems (Pit or Pst) prompts the influx of K+ and H+ in a ratio that depends on the external pH. The entry of Pi is absolutely dependent on the presence of K+, and the entry of K+ is equally dependent on the presence of Pi. Experiments with a number of mutants carrying any one functional Pi-transport system and one or more of the individual K+-transport systems indicate a permissive type of linkage of the two transports, in that there is no obvious preference by any of the Pi-transport systems for a particular K+-transport system for the concomitant entry of the two ions.     

The proton electrochemical gradient in Escherichia coli cells.

The internal pH of Escherichia coli cells was estimated from the distribution of either 5,5-[14C]dimethyl-2,4-oxazolidinedione or [14C]methylamine. EDTA/valinomycin treatment of cells was employed to estimate delta psi from 86Rb+ distribution concomitant with the delta pH for calculation of delta muH. Respiring intact cells maintained an internal pH more alkaline by 0.63-0.75 unit than that of the milieu at extracellular pH 7, both in growth medium and KCl solutions. The delta pH decreased when respiration was inhibited by anaerobiosis or in the presence of KCN. The delta muH, established by EDTA/valinomycin-treated cells, was constant (122-129 mV) over extracellular potassium concentration of 0.01 mM-1 mM. At the lower potassium concentration delta psi (110-120 mV) was the predominant component, and at the higher concentration delta pH increased to 0.7 units (42 mV). At 150 mM potassium delta muH was reduced to 70 mV mostly due to a delta pH component of 0.89 (53 mV). The interchangeability of the delta muH components is consistent with an electronic proton pump and with potassium serving as a counter ion in the presence of valinomycin. Indeed both parameters of delta muH decreased in the presence of carbonylcyanide p-trifluoromethoxyphenylhydrazone. The highest delta pH of 2 units was observed in the intact cells at pH 6; increasing the extracellular pH decreased the delta pH to 0 at pH 7.65 and to -0.51 at pH 9. A similar pattern of dependence of delta pH on extracellular pH was observed in EDTA/valinomycin-treated cells but the delta psi was almost constant over the whole range of extracellular pH values (6-8) implying electroneutral proton movement. Potassium is specifically required for respiration of EDTA-treated E. coli K12 cells since other monovalent or divalent cations could not replace potassium and valinomycin was not required.     

Calcium transport driven by a proton gradient and inverted membrane vesicles of Escherichia coli.

Calcium transport into inverted vesicles of Escherichia coli was observed to occur without an exogenous energy source when an artificial proton gradient was used. The orientation of the proton gradient was acid inside and alkaline outside. Either phosphate or oxalate was necessary for transport, as was found for respiratory-driven or ATP-driven uptake (Tsuchiya, T., and Rosen, B.P. (1975) J. Biol. Chem. 250, 7687-7692). Phosphate accumulation was found to occur in conjunction with calcium accumulation. Calcium transport driven by an artificial proton gradient was stimulated by dicyclohexylcarbodiimide, an inhibitor of the Mg2+ATPase (EC 3.6.1.3). Valinomycin, which catalyzes electrogenic potassium movement, stimulated calcium accumulation, while nigericin, which catalyzes electroneutral exchange of potassium and protons, inhibited both artificial proton gradient-driven transport and respiratory-driven transport. Other properties of the proton gradient-driven system and the previously reported energy-linked calcium transport system are similar, indicating that calcium is transported by the same carrier whether energy is supplied through an artificial proton gradient or an energized membrane state. These results suggest the existence of a calcium/proton antiport.     

Relation of potassium uptake to proton transport and activity of hydrogenases in Escherichia coli grown at low pH

Escherichia coli grown under anaerobic conditions in acidic medium (pH 5.5) upon hyperosmotic stress accumulates potassium ions mainly through the Kup system, the functioning of which is associated with proton efflux decrease. It was shown that H⁺ secretion but not glucose-induced K⁺ uptake was inhibited by N,N′-dicyclohexylcarbodiimide (DCC). The inhibitory effect of DCC on the H⁺ efflux was stronger in the trkA mutant with defective potassium transport. The K⁺ and H⁺ fluxes depended on the extent of hyperosmotic stress in the absence or presence of DCC. The decrease in external oxidation/reduction potential and H₂ liberation insensitive to DCC were recorded. It was found that the atpD mutant with nonfunctional F₀F₁-ATPase produced a substantial amount of H₂, while in the hyc mutant (but not the hyf mutant defective in hydrogenases 3 (Hyd-3) and 4 (Hyd-4)) the H₂ production was significantly suppressed. At the same time, the rate of K⁺ uptake was markedly lower in hyfR and hyfB-R but not in hycE or hyfA-B mutants; H⁺ transport was lowered and sensitive to DCC in hyf but not in hyc mutants. The results point to the relationship of K⁺ uptake with the Hyd-4 activity. Novel options of the expression of some hyf genes in E. coli grown at pH 5.5 are proposed. It is possible that the hyfB-R genes expressed under acidic conditions or their gene products interact with the gene coding for the Kup protein or directly with the Kup system.     

Glutamate transport driven by an electrochemical gradient of sodium ions in Escherichia coli.

The role of Na+ in glutamate transport was studied in Escherichia coli B, strain 29-78, which possesses a very high activity of glutamate transport (L. Frank and I. Hopkins, J. Bacteriol., 1969). Energy-depleted cells were exposed to radioactive glutamate in the presence of a sodium gradient, a membrane potential, or both. One hundred- to 200-fold accumulation of the amino acid was attained in the presence of both electrical and chemical driving forces for the sodium ion. Somewhat lower accumulation values were obtained when either chemical or electrical driving forces were applied separately. A chemical driving force was produced by the addition of external Na+ to Na+-free cells. A membrane potential was established by a diffusion potential either of H+ in the presence of carbonyl cyanide p-trifluoromethoxyphenylhydrazone or of SCN-. These results support the hypothesis of a Na+-glutamate cotransport. Na+-driven glutamate transport was also observed in wild-type E. coli B but not in a strain of K-12.     

The tet(K) gene from Staphylococcus aureus mediates the transport of potassium in Escherichia coli.

The tet(K) gene, encoding the tetracycline efflux protein from Staphylococcus aureus, mediates the transport of potassium in an Escherichia coli mutant defective in potassium uptake. Deletion mapping indicates that the first third of the tet(K) gene is sufficient to mediate potassium transport.     

The role of ribose-binding protein in transport and chemotaxis in Escherichia coli K12.

The ribose-binding protein of Escherichia coli [Willis, R. C., and Furlong, C. E. (1974) J. Biol. Chem.249, 6926–6929] has been shown to be a required common receptor component for high-affinity ribose transport and for chemotaxis toward this attractant. Mutants devoid of the ribose-binding protein are missing high-affinity ribose transport and do not respond chemotactically to this sugar, whereas the response to other attractants is normal. Eight independently isolated ribose-positive revertant strains regained the binding protein, high-affinity ribose transport, and ribose chemotaxis. One revertant which grows slowly on ribose as a sole carbon source did not regain the binding protein, high-affinity transport, or ribose chemotaxis.